• No results found

SEATTLE STEAM COMPANY COMBINED HEAT AND POWER AT POST AVENUE IN DOWNTOWN SEATTLE, WASHINGTON

N/A
N/A
Protected

Academic year: 2021

Share "SEATTLE STEAM COMPANY COMBINED HEAT AND POWER AT POST AVENUE IN DOWNTOWN SEATTLE, WASHINGTON"

Copied!
75
0
0

Loading.... (view fulltext now)

Full text

(1)

DRAFT

ENVIRONMENTAL ASSESSMENT

FOR

SEATTLE STEAM COMPANY

COMBINED HEAT AND POWER AT

POST AVENUE IN DOWNTOWN

SEATTLE, WASHINGTON

U.S. Department of Energy

National Energy Technology Laboratory

June 2010

(2)
(3)

DRAFT

ENVIRONMENTAL ASSESSMENT

FOR

SEATTLE STEAM COMPANY

COMBINED HEAT AND POWER AT

POST AVENUE IN DOWNTOWN

SEATTLE, WASHINGTON

U.S. Department of Energy

National Energy Technology Laboratory

June 2010

(4)

ACRONYMS AND ABBREVIATIONS

Btu British thermal unit CFR Code of Federal Regulations CHP combined heat and power CO carbon monoxide dB(A) A-weighted decibel

DOE U.S. Department of Energy (also called the Department) EA environmental assessment

EPA U.S. Environmental Protection Agency FR Federal Register

NEPA National Environmental Policy Act, as amended NOX nitrogen oxides

PM10 particulate matter with median aerodynamic diameter of 10 micrometers or less PM2.5 particulate matter with median aerodynamic diameter of 2.5 micrometers or less PSD prevention of significant deterioration

PSCAA Puget Sound Clean Air Agency PSE Puget Sound Energy

Recovery Act American Recovery and Reinvestment Act of 2009 SMC Seattle Municipal Code

VOC volatile organic compound

Note: Numbers in this EA generally have been rounded to two or three significant figures. Therefore, some total values might not equal the actual sums of the values.

(5)

COVER SHEET

RESPONSIBLE AGENCY: U.S. Department of Energy (DOE)

TITLE: Draft Environmental Assessment (Draft EA) for Seattle Steam Company Combined

Heat and Power at Post Avenue in Downtown Seattle, Washington (DOE/EA-1741D)

CONTACT: For additional copies, more information, or to provide comments concerning this

draft environmental assessment (Draft EA), please contact: Mark W. Lusk

Office of Project Facilitation & Compliance U.S. Department of Energy

National Energy Technology Laboratory 3610 Collins Ferry Road

P.O. Box 880, MS B07

Morgantown, WV 26507-0880 Facsimile: (304) 285-4403 Email: mark.lusk@netl.doe.gov.

Abstract: DOE prepared this Draft EA to evaluate the potential environmental consequences of

providing an American Recovery and Reinvestment Act of 2009 (Recovery Act; Public Law

111-5, 123 Stat. 115) financial assistance grant to the Seattle Steam Company to facilitate the installation of a combined heat and power (CHP) plant in downtown Seattle, Washington. The CHP plant would be integrated into the existing electrical and thermal energy distribution networks and capable of producing about 50 megawatts of electricity as well as providing steam to Seattle Steam’s existing energy distribution system. This Draft EA analyzes the potential environmental consequences of DOE’s Proposed Action of providing the Recovery Act grant, Seattle Steam Company’s proposed project of installing and operating a CHP system, and the No-Action Alternative.

In this Draft EA, DOE evaluated in detail potential impacts to air quality, cultural resources, socioeconomics, health and safety, sound levels, and energy use. After performing a screening analysis of other resource areas, DOE concluded that impacts to other aspects of the environment would not occur or would not be detectable. The proposed project would be in compliance with federal and Washington air quality regulations, reduce greenhouse gas emissions, and have a net beneficial impact on air quality in the region. The CHP system would be installed in a facility of historic significance, which would require some temporary and, perhaps, permanent changes to the building’s exterior. Seattle Steam would take measures to maintain the building’s

characteristics as well as make structural improvements to the interior that would increase the building’s longevity. Manufacturing and installation of the equipment would result in a minor to moderate, temporary beneficial impact to the economy. Operation of the CHP system would add an increment of sound levels to the local area but would be in compliance with the city’s Noise

(6)

Control ordinance. Cumulative impacts from the proposed project, relative to impacts from other activities in the surrounding area, would be negligible to small.

Availability: The Draft EA is available on DOE’s National Energy Technology Laboratory

(NETL) web site (http://www.netl.doe.gov/publications/others/nepa/ea.html) and at the following public library:

The Seattle Public Library Central Library

1000 Fourth Avenue Seattle, WA 98104-1109

(7)

Contents

CONTENTS

Section Page

Summary ... ix

1. Introduction ... 1

1.1 National Environmental Policy Act and Related Procedures ... 1

1.2 Background ... 2

1.3 Purpose and Need ... 3

1.4 Environmental Resources Not Carried Forward ... 4

2. DOE Proposed Action and Alternatives ... 8

2.1 DOE’s Proposed Action ... 8

2.2 Seattle Steam’s Proposed Project ... 8

2.3 Alternatives ... 14

2.4 No-Action Alternative ... 14

3. Affected Environment and Environmental Consequences ... 15

3.1 Air Quality ... 15

3.1.1 Affected Environment ... 15

3.1.2 Environmental consequences ... 16

3.1.2.1 Proposed Project ... 16

3.1.2.1.1 Air Quality Conformity ... 18

3.1.2.1.2 Greenhouse Gas Emissions ... 19

3.1.2.2 No-Action Alternative ... 19

3.2 Cultural Resources ... 20

3.2.1 Affected Environment ... 20

3.2.1.1 Historic Background ... 20

3.2.1.2 Status of Cultural Resource Inventories and Section 106 Consultations ... 21

3.2.2 Environmental consequences ... 26

3.2.2.1 Proposed Project ... 26

3.2.2.2 No-Action Alternative ... 28

3.3 Socioeconomics ... 28

(8)

Contents

3.3.2 Environmental consequences ... 29

3.3.2.1 Proposed Project ... 29

3.3.2.2 No-Action Alternative ... 30

3.4 Occupational Health and Safety ... 30

3.4.1 Affected Environment ... 30

3.4.2 Environmental consequences ... 31

3.4.2.1 Proposed Project ... 31

3.4.2.1.1 Construction and Manufacturing ... 31

3.4.2.1.2 Operations ... 32 3.4.2.2 No-Action Alternative ... 32 3.5 Noise ... 32 3.5.1 Affected Environment ... 32 3.5.2 Environmental consequences ... 34 3.5.2.1 Proposed Project ... 34 3.5.2.2 No-Action Alternative ... 35

3.6 Utilities, Energy, and Materials ... 35

3.6.1 Affected Environment ... 36 3.6.1.1 Electricity ... 36 3.6.1.2 Natural Gas ... 36 3.6.2 Environmental consequences ... 37 3.6.2.1 Proposed Project ... 37 3.6.2.1.1 Electricity ... 37 3.6.2.1.2 Natural Gas ... 38 3.6.2.2 No-Action Alternative ... 39

3.7 The Relationship between Local Short-Term Uses of the Environment and the Maintenance and Enhancement of Long-Term Productivity ... 39

3.8 Irreversible and Irretrievable Commitments of Resources ... 39

3.9 Unavoidable Adverse Impacts ... 39

4. Cumulative Impacts ... 41

4.1 Reasonably Foreseeable Actions ... 41

4.1.1 Forecasts by the Seattle Department of Planning and Development ... 41

4.1.2 Forecasts by puget sound energy ... 42

4.1.3 Other Foreseeable Actions ... 43

(9)

Contents

4.2.1 Air Quality ... 44

4.2.2 Cultural Resources ... 44

4.2.3 Socioeconomics ... 44

4.2.4 Occupational Heath and Safety ... 44

4.2.5 Noise ... 45

4.2.6 Utilities, Energy, and Materials ... 45

5. Conclusions ... 46

6. References ... 48

LIST OF TABLES

Table Page 1-1 Resource areas with no or minimal impacts ...5

3-1 National Ambient Air Quality Standards and air quality data for King County, Washington in 2006, 2007, and 2008 ...16

3-2 Preliminary estimates of air emissions from the Seattle Steam proposed CHP plant compared with existing energy plant permit limits and King County total emissions ...17

3-3 Properties on the National Resister of Historic Places within 0.5 mile of the proposed project site ...22

3-4 Summary of socioeconomic characteristics for King County and Seattle ...28

3-5 Summary of maximum acceptable sound levels as set by Seattle code ...33

LIST OF FIGURES

Figure Page 2-1 Locations of Seattle Steam’s energy generation plants and district energy system ...9

2-2 Aerial view of the Seattle Steam plant on Post Avenue, Seattle ...10

2-3 Generic representation of a CHP plant as would be deployed by Seattle Steam ...10

2-4 Photograph of the Seattle Steam plant at 633 Post Avenue, showing the western side of the building and a portion of the Old Post Station ...13

2-5 Interior views of the Seattle Steam plant at 633 Post Avenue, showing the steel frame and concrete floor construction...13

(10)
(11)

Summary

SUMMARY

The U.S. Department of Energy proposes to award an American Recovery and Reinvestment Act of 2009 financial assistance grant to the Seattle Steam Company to facilitate the installation of a

new combined heat and power system at an existing district energy plant that supplies steam to about 200 buildings in about 1 square mile of Seattle, Washington’s, Central Business District and First Hill neighborhoods. The Department’s Proposed Action is to provide Seattle Steam Company with an $18.8 million grant in a cost-sharing arrangement to facilitate installation of the combined heat and power system. The system would have the capacity to produce about 50 megawatts of electricity and, along with another energy plant, support steam demand from the district energy distribution system. Seattle Steam estimates the proposed plant would use only about 60 percent as much fuel as the current steam and electricity generating capacity it would replace.

The combined heat and power system would be installed in the Seattle Steam Company’s existing facility at 633 Post Avenue in south downtown Seattle. Electricity from the system would be produced using a natural gas-powered combustion turbine. The exhaust gas from the turbine would be routed to a once-through (heat recovery) steam generator, which would be equipped with natural gas-fired duct burners to increase steam production. Excess steam from the steam generator would be routed through a steam turbine, providing a secondary electricity generation source. Steam would be sent to the district energy distribution system from either the steam generator or steam turbine. A selective catalytic reduction system would be installed in the off-gas system to reduce emissions of nitrogen oxides.

Seattle Steam’s facility is located in an area classified under the Clean Air Act as “in attainment”

for all criteria air pollutants. An estimated 23 tons of carbon monoxide, 19 tons of nitrogen oxides, and 83 tons of particulate matter would be emitted per year during operation of the system. These emissions would be expected to be generally higher than those currently emitted from the existing facility and prior to construction and operation of the new system, Seattle Steam would obtain the necessary permits and air emission limitations to ensure compliance with federal and Washington air quality regulations. Although emissions from the existing facility would increase, operation of the combined heat and power system would result in a net decrease in air pollutant emissions by offsetting emissions from the current steam plant and regional electricity generating plants. Thus, the project would have a net beneficial impact on air quality in the region.

The Seattle Steam facility is within the Pioneer Square – Skid Road Historic District, which is on both the Washington Heritage Register and the National Register of Historic Places. The

building itself is identified as a contributing source to the Pioneer Square District’s placement on the National Register. As such, the proposed project would affect a building of historic

significance. Temporary changes would likely be required to the building’s façade and possibly permanent changes to the building’s roof in order to incorporate necessary air handling

(12)

Summary

maintain the characteristics that made it eligible for the National Register of Historic Properties. The interior actions would include structural improvements that should help extend the life of the building. The Pioneer Square Preservation Board would need to review and approve detailed plans before Seattle Steam began facility modification and restoration activities. DOE concludes that the proposed project would maintain the cultural significance of the existing building. Installation and operation of the combined heat and power system would not have any

meaningful or detectable impacts on land use; geology and soils; water, biological, and visual resources; waste and hazardous materials; environmental justice; and transportation and traffic. Further, operation of the system would not cause significant hazards to workers or the public. Manufacturing of the combined heat and power equipment would result in a minor to moderate and mostly temporary, beneficial impact to the economy in the areas where the equipment would be manufactured and in the Seattle area during installation and subsequent operation.

The proposed project would cause unavoidable increases in noise within the existing facility The City of Seattle’s Noise Control ordinance would require the facility to create no more than 60 dB(A) of sound at adjacent receptors. Achieving the City’s required noise reduction level would ensure that there would be no significant noise impacts to people or property use in the area. Operation of the combined heat and power system would require more natural gas (or diesel fuel in times of natural gas curtailment) than currently being used at the existing facility. However, this would be offset by the production of electricity that would go to the region’s electrical grid. Overall, the system would use less fuel energy than currently being used to produce the

corresponding amounts of steam (in the Seattle Steam boiler plant) and electricity (in regional generating units).

Relative to the cumulative changes in the environment from ongoing and planned activities in south downtown Seattle, installation and operation of the combined heat and power system would cause small, adverse incremental changes in air quality and noise in the area. The

increasing demand for electricity and natural gas in the future will undoubtedly increase the need for more efficient uses of fuel, such as that provided with a combined heat and power system. Under the No-Action Alternative, DOE would not provide funding to Seattle Steam and assumes for purposes of this analysis that the combined heat and power system would not be installed and operated. No impacts to the existing environment would occur, and beneficial impacts of the proposed project would not be realized.

On the basis of the evaluations in this environmental assessment, the Department of Energy determined that its Proposed Action, providing financial assistance to Seattle Steam to facilitate installation of a combined heat and power system, would have no significant impact on the human environment.

(13)

Introduction

1. INTRODUCTION

As part of the American Recovery and Reinvestment Act of 2009 (the Recovery Act; Public

Law 111-5, 123 Stat. 115), the U.S. Department of Energy (DOE) National Energy Technology Laboratory (NETL), on behalf of the Office of Energy Efficiency and Renewable Energy’s Industrial Technologies Program, is providing up to $156 million in federal funding for competitively awarded grants for the deployment of projects for district energy systems,

combined heat and power (CHP) systems, waste energy recovery systems, and energy-efficient industrial equipment and processes at single installations or multiple installations at multiple sites. The funding of these projects requires compliance with the National Environmental Policy Act of 1969, as amended (NEPA; 42 U.S.C. 4321 et seq.), Council on Environmental Quality

regulations (40 CFR Parts 1500 to 1508), and DOE NEPA implementing regulations (10 CFR Part 1021).

To comply with NEPA, DOE has prepared this Draft Environmental Assessment for Seattle Steam Company Combined Heat and Power at Post Avenue in Downtown Seattle, Washington

(Draft EA). This Draft EA examines the potential environmental consequences of DOE’s Proposed Action—providing a financial assistance grant—and the Seattle Steam Company’s (Seattle Steam’s) proposed project—transitioning one of their existing steam energy plants in downtown Seattle, Washington, into a CHP plant. Under this project equipment already in the plant would be removed as necessary and new equipment would be installed with the capacity to more efficiently produce both electricity and steam. Seattle Steam would continue to utilize the steam in their existing distribution system and the electricity produced would be purchased by an electrical utility in the area. This EA also examines the No-Action Alternative, under which DOE would not provide the proposed financial assistance and, for purposes of this evaluation, assumes Seattle Steam would not proceed with the project.

This section explains NEPA and the related procedures (Section 1.1), the background of this project (Section 1.2), its purpose and need (Section 1.3), and the environmental considerations DOE did not carry forward to detailed analysis (Section 1.4). Chapter 2 discusses DOE’s Proposed Action, Seattle Steam’s proposed project, action alternatives, and the No-Action Alternative. Chapter 3 details the affected environment and potential environmental consequences of the Proposed Action, proposed project, and of the No-Action Alternative. Chapter 4 addresses cumulative impacts, and Chapter 5 provides DOE’s conclusions from the analysis. Chapter 6 lists the references for this document. Appendix A contains the distribution list for this document, and Appendix B lists consultations with other agencies.

1.1 National Environmental Policy Act and Related Procedures

In accordance with the DOE NEPA implementing procedures, DOE must evaluate the potential environmental impacts of its proposed actions, including funding decisions, which may have a significant impact on human health or the environment. In compliance with these regulations and DOE’s procedures, this EA:

(14)

Introduction

 Examines the potential environmental impacts of the Proposed Action and the No-Action Alternative;

 Identifies unavoidable adverse environmental impacts of the Proposed Action;  Describes the relationship between local short-term uses of the environment and the

maintenance and enhancement of long-term productivity; and

 Characterizes any irreversible and irretrievable commitments of resources that would be involved should DOE decide to implement its Proposed Action.

DOE must meet these requirements before it can make a final decision to proceed with any proposed federal action that could cause adverse impacts to human health or the environment. This EA fulfills DOE’s obligations under NEPA and provides DOE with the information needed to make an informed decision about helping finance Seattle Steam Company’s proposed

installation of a CHP system in downtown Seattle, Washington.

This EA evaluates the potential individual and cumulative impacts of Seattle Steam Company’s project. No other action alternatives are analyzed. For purposes of comparison, this EA also evaluates the impacts that could occur if DOE did not provide funding (the No-Action

Alternative), under which DOE assumes that Seattle Steam Company would not proceed with the project. This assumption may be incorrect—that is, Seattle Steam might proceed without federal assistance. However, this assumption allows DOE to compare the impacts of an alternative in which the project occurs with one in which it does not.

1.2 Background

The U.S. Department of Energy’s (DOE’s or The Department’s) National Energy Technology Laboratory (NETL) manages the research and development portfolio of the Industrial

Technologies Program for the Office of Energy Efficiency and Renewable Energy. The mission of the Industrial Technologies Program is to establish U.S. industry as a world leader in energy efficiency and productivity. The program leads the national effort to reduce industrial energy intensity and carbon emissions, and strives to transform the way U.S. industry uses energy by supporting cost-shared research and development that addresses the top energy challenges facing industry. In addition, the Industrial Technologies Program fosters the adoption of advanced technologies and energy management best practices to produce meaningful progress in reducing industrial energy intensity.

Congress appropriated significant funding for the Industrial Technologies Program in the Recovery Act to stimulate the economy and reduce unemployment in addition to furthering the objectives of the existing program. DOE solicited applications for this funding by issuing a competitive Funding Opportunity Announcement (DE-FOA-0000044), Recovery Act: Deployment of Combined Heat and Power (CHP) Systems, District Energy Systems, Waste

(15)

Introduction

Energy Recovery Systems, and Efficient Industrial Equipment, in June, 2009. The announcement

invited applications in four areas of interest:

 Area of Interest 1 – Combined Heat and Power; the generation of electric energy and heat in a single, integrated system, with an overall thermal efficiency of 60 percent or greater on a higher-heating-value basis.

 Area of Interest 2 – District Energy Systems; systems providing thermal energy from a renewable energy source, thermal energy source, or highly efficient technology to more than one building or fixed energy-consuming use from one or more thermal energy production facilities through pipes or other means to provide space heating, space conditioning, hot water, steam, compression, process energy, or other end uses.

 Area of Interest 3 – Industrial Waste Energy Recovery; the collection and reuse of energy from sources such as exhaust heat or flared gas from any industrial process; waste gas or industrial tail gas that would otherwise be flared, incinerated, or vented; or a pressure drop in any gas, excluding any pressure drop to a condenser that subsequently vents the resulting heat.

 Area of Interest 4 – Efficient Industrial Equipment; any proven commercially available technology that can provide a minimum 25-percent efficiency improvement to the industrial sector.

The Department announced its selections on November 3, 2009, with multiple awards in three of the four areas of interest and selected 9 projects based on the evaluation criteria in the funding opportunity announcement and gave special consideration to projects that promoted the objectives of the Recovery Act—job preservation or creation and economic recovery—in an expeditious manner.

This proposed project, installation of a CHP system at Post Avenue in downtown Seattle, was one of the 9 selected for funding by DOE. The Department’s Proposed Action is to provide an $18.8 million in financial assistance grant under a cost-sharing arrangement with Seattle Steam Company. The total cost of the project is estimated at $80 million.

1.3 Purpose and Need

The purpose of the Proposed Action is to support the mission of DOE’s Industrial Technologies Program and the goals of the Recovery Act. The mission of the Industrial Technologies Program is to have U.S. industry lead the world in energy efficiency and productivity. The Program leads the national effort to reduce industrial energy intensity and carbon emissions, and strives to transform the way U.S. industry uses energy by supporting cost-shared research and

development that addresses the top energy challenges facing industry. Additionally, the Program fosters the adoption of today's advanced technologies and energy management best practices to produce meaningful progress in reducing industrial energy intensity.

(16)

Introduction

The Industrial Technologies Program’s three-part strategy pursues this mission by:  Sponsoring research, development, and demonstration of industry-specific and

crosscutting technologies to reduce energy and carbon intensity;

 Conducting technology delivery activities to help plants access today’s technology and management practices; and

 Promoting a corporate culture of energy efficiency and carbon management within industry.

To align with its mission, the program has established a goal of achieving a 25-percent reduction in industrial energy intensity by 2017, guided by the Energy Policy Act of 2005. The strategy

also calls for an 18-percent reduction in U.S. carbon intensity by 2012. The Department seeks to identify projects and technologies that it can fund to meet this goal.

In June 2009, DOE initiated a process to identify suitable projects by issuing Funding

Opportunity Announcement DE-FOA-00000044, Recovery Act: Deployment of Combined Heat and Power (CHP) Systems, District Energy Systems, Waste Energy Recovery Systems, and Efficient Industrial Equipment. This Funding Opportunity Announcement is funded by the

Recovery Act.

The Recovery Act seeks to create jobs, restore economic growth, and strengthen America's middle class through measures that modernize the nation's infrastructure, enhance America's energy independence, expand educational opportunities, preserve and improve affordable health care, provide tax relief, and protect those in greatest need. Provision of funds under this Funding Opportunity Announcement would achieve these objectives.

The capital cost of new equipment is often a roadblock for use of more efficient equipment and processes. Although the newer technologies would provide lower energy requirements and operating costs, the payback period for some technologies does not meet internal business goals. DOE’s provision of financial assistance allows companies to reduce the payback period, making these new technologies an acceptable option for them.

1.4 Environmental Resources Not Carried Forward

Chapter 3 of this EA examines the potential environmental impacts of the proposed Seattle Steam project and No-Action Alternative in the following resource areas:

 Air quality,

 Cultural resources,  Socioeconomics,

 Occupational health and safety,  Noise, and

(17)

Introduction

 Utilities, energy, and materials.

The Department’s EAs commonly address the resource areas in Table 1-1 in addition to those identified above. However, in an effort to streamline the NEPA process and enable timely awards to the selected projects, this assessment did not examine these areas at the same level of detail as the resource areas listed above. The focus for the more detailed analysis was on those activities or actions that would require new or revised permits, have the potential for significant adverse environmental impacts, or have the potential for controversy. DOE concludes that the Seattle Steam proposed project would result in no or very minor impacts to the resource areas in Table 1-1, which includes explanations for why further analysis is unnecessary.

Table 1-1. Resource areas with no or minimal impacts.

Resource area Reasons for Not Requiring a Detailed Analysis

Land Use The new equipment would be installed in the existing Seattle Steam boiler plant on Post Avenue. Seattle Steam owns the existing facility, which has provided energy services to the core area of downtown Seattle for over 115 years. Installation of the new CHP system would improve the efficiency of the Seattle Steam district energy system and would not disrupt the primary land use, which is an industrial facility to generate steam for an existing district energy system. Although this location is in downtown Seattle and within the Pioneer Square – Skid Road National Historic District, the historic use of the facility has been as an energy generation plant. The project would involve no change in land use at this or surrounding locations.

Geology and Soils Because the new equipment would go into an existing facility, the project would have no affect on geology and soils of the area. Similarly, geologic and soil conditions would have no different effect than on the current facility, with the exception that the interior of the building would undergo an extensive

renovation, including actions to strengthen its structure to meet current building codes. It is recognized that Seattle, Washington is in an active seismic area (USGS 2008), so actions to strengthen the facility could be important with regard to its longevity and the longevity of the new equipment.

Water Resources Water use during construction and equipment installation actions would be minor and basically limited to the personal needs of the workers and possibly the cleaning of building materials and tools. Similarly, there would be no discharges of wastewater, other than the minor increases in the quantities going to the existing sewer system as a result of the additional workers that would be present during construction and from rinsing done inside the building.

The new CHP plant would produce quantities of steam similar to those currently produced by the existing plant. Therefore, there would be no significant change in the amount of water that would be required by the operating CHP plant. Housed within an existing facility, the new CHP plant would involve no change to existing storm water runoff quantities or quality. Existing discharge of soft water regenerant solution from the energy plant is to the bay and is done under a permit. These conditions would not change.

(18)

Introduction

Table 1-1. Resource areas with no or minimal impacts (continued).

Resource area Reasons for Not Requiring a Detailed Analysis

Biological Resources Since all project activities would take place within an existing building, there would be no potential for impacting biological resources. This would include no potential to impact any threatened or endangered species and, as a result, there would be no reason for consultations with the U.S. Fish and Wildlife Service (FWS) under Section 7(a) (2) of the Endangered Species Act. This was verified in an informal conversation with a manager from the Washington Fish and Wildlife Office of the FWS (Michaels 2010).

Aesthetics and Visual Resources

During construction and equipment installation, there would be increased activities at and around the existing Seattle Steam energy plant on Post Avenue. Some observers may find this disruptive of the aesthetic and visual values of the immediate area, but these activities would be temporary and of relatively short duration.

Once the CHP plant was operational, aesthetic and visual resources of the area would be no different than under current conditions for the existing facility. There would be no, or very minor, changes to the exterior of the building. There could be minor changes on the roof of the existing building in the form of air handling devices for the new equipment, but these would not be visible from ground level. As a property of historical value, the existing energy plant’s visual characteristics are further addressed in Section 3.2.

Waste and Hazardous

Materials It is expected that only minor amounts of construction debris waste would be generated during the proposed project’s construction and equipment installation phase. Some old, asbestos-covered equipment would likely be removed from the facility before the new equipment would be installed. Seattle Steam has personnel certified to manage asbestos removal actions and both the asbestos containing materials and the equipment, as well as any other construction debris would be managed and disposed of in accordance with local regulations. Fuels and other petroleum products used in construction equipment would be present at the site during construction. Any significant spillage or leakage from this equipment would be cleaned up at the time it occurred. There would be no significant quantities of hazardous materials present at the site during operations other than the possible lubricants and cleaning materials present inside the facility to support equipment and facility maintenance actions.

(19)

Introduction

Table 1-1. Resource areas with no or minimal impacts (continued).

Resource area Reasons for Not Requiring a Detailed Analysis Environmental

Justice

Executive Order 12898, “Federal Actions to Address Environmental Justice in Minority Populations and Low-Income Populations,” directs federal agencies to address environmental and human health conditions in minority and low-income communities. The evaluation of impacts to environmental justice is dependent on determining if high and adverse impacts from the proposed project would disproportionately affect any low-income or minority group in the affected community. The Department determined that no high and adverse impacts would occur to any member of the community; therefore it was determined there would be no adverse and disproportionate impacts to minority or low-income populations. Section 3.3.1 presents demographic information for the area. Transportation During construction and equipment installation actions, workers at the existing

energy plant would represent an increase in the local area workforce that would be vying for the same public parking places and public transportation capacity as the existing workforce. There would be no new or unique parking places made available for the construction workers. However, the size of the construction workforce would be minor in comparison to workers already in the area and the additional demands on public parking and transportation would be temporary. It is anticipated that limited (and temporary) road lane modifications would be necessary for safe delivery of large pieces of equipment, but the number of such actions would be relatively small and would be coordinated with local traffic management authorities.

(20)

DOE Proposed Action and Alternatives

2. DOE PROPOSED ACTION AND ALTERNATIVES

This chapter describes DOE’s Proposed Action (Section 2.1), Seattle Steam’s proposed project (Section 2.2), the bases for not considering other alternatives (Section 2.3), and the No-Action Alternative (Section 2.4).

2.1 DOE’s Proposed Action

The Department of Energy’s Proposed Action for the Industrial Technologies Program is to provide Seattle Steam with a financial assistance grant through the Recovery Act to facilitate Seattle Steam’s installation of a CHP plant in downtown Seattle. DOE would provide an $18.8 million grant in a cost-sharing arrangement with Seattle Steam. The total cost of the proposed project is estimated to be $80 million.

2.2 Seattle Steam’s Proposed Project

Seattle Steam’s proposed project would install a new CHP system, with the capacity to generate approximately 50 megawatts of electricity, within an existing energy plant in downtown Seattle, Washington. The proposed project would improve energy efficiency by producing electricity as well as contributing steam to an existing steam distribution system.

Seattle Steam is a privately owned utility, founded in 1893, that currently operates a district energy system in Seattle, Washington. Seattle Steam produces thermal energy (steam) from five boilers in two plants located in downtown Seattle, and distributes the energy through

approximately 18 miles of underground pipe to about 200 buildings in 1 square mile of Seattle’s Central Business District and First Hill neighborhoods. Buildings served by the district energy system include office buildings, hospitals, hotels, and college campuses (Seattle Steam 2010a). Figure 2-1 shows the locations of the two energy plants and the approximate extent of the district energy system.

Seattle Steam operates five boilers in its two energy plants, four in the plant on Western Avenue and one in the plant on Post Avenue. The Seattle Steam boilers used natural gas, diesel (No. 2) fuel oil, or residual (No. 6) fuel oil. Natural gas is the primary fuel and fuel oil is used as

secondary or standby fuel source, used primarily during periods of natural gas curtailment. This was changed slightly in the fall of 2009 when Seattle Steam started using its first biomass boiler. The primary fuel source for this boiler is urban waste wood, including materials such as woody yard waste, broken wood pallets, clean construction demolition wood, and wood waste from sawmills. The new boiler system provides Seattle Steam additional flexibility and price stability in the fuels it uses to produce energy.

Seattle Steam’s proposed project would transition its plant on Post Avenue (Figures 2-1 and 2-2), into a combined heat and power (CHP) plant. Under this project, non-operating existing boiler equipment in the Post Avenue plant would be removed if necessary and new equipment would be installed with the capacity to produce both electricity and steam. With the new equipment

(21)

DOE Proposed Action and Alternatives

configuration, a gas turbine would be used to produce electricity. Heat from this process would be recovered by being sent through a heat recovery steam generator for the production of steam. As another energy recovery step, the CHP plant would include a steam generator that would provide additional electricity and a combined cycle design. Figure 2-3 provides a generic

Figure 2-1. Locations of Seattle Steam’s energy generation plants and district energy

system.

representation of the equipment configuration that would be used in the CHP plant. As depicted in the figure, steam would be diverted to the Seattle Steam distribution system from the outlet of the steam turbine. In addition, low pressure steam is generated at the low temperature end of the heat recovery steam generator to further increase efficiency. Electricity would be transmitted to the electrical grid from both the gas turbine and the steam turbine.

(22)

DOE Proposed Action and Alternatives

Figure 2-2. Aerial view of the Seattle Steam plant on Post Avenue, Seattle.

(23)

DOE Proposed Action and Alternatives

The gas turbine would use natural gas as its primary fuel with No. 2 fuel oil as its secondary fuel, and would produce electricity as well as provide heat to the steam generator. The steam

generator (designated as a once-through steam generator) would use the hot exhaust from the gas turbine to generate steam, which would be sent to the steam turbine (with the option of also producing low pressure steam). This once-through configuration also allows the generator to be left dry, so if steam is not needed, the gas turbine could still be used to produce electricity without requiring the exhausted heat to bypass the generator. Seattle Steam’s proposed CHP configuration also allows supplemental firing of fuel at the duct between the gas turbine and the steam generator. Fuel added at this point of the system takes advantage of the preheated

combustion air and the relatively high concentration of oxygen remaining in the gas turbine exhaust to significantly increase the amount of steam that can be produced in the steam

generator. Supplemental firing at this point in the system produces an increment of steam more efficiently (uses less fuel) than a comparable increment of steam from a stand-alone boiler (EPA 2008).

CHP systems typically require about three-quarters as much primary energy as that used by separate heat and power systems (EPA 2008). Seattle Steam estimates its proposed CHP system would be even more efficient, using only about 60 percent as much energy as would otherwise be used by separate power and heat systems fueled with coal, petroleum, or natural gas (Gent 2010).

As Figure 2-3 shows, excess steam from the steam generator would pass through the back pressure steam turbine for another source of electricity production. The amount of steam used to produce electricity could be varied depending on the process needs and the remaining steam would travel to the distribution system. The combination of these primary CHP components would allow the operator wide flexibility in making the most efficient use of the fuel energy originally sent to the gas turbine, while still meeting the demands for steam production.

The flow of air through the CHP system is only partially shown in Figure 2-3. Air going through the gas turbine would be exhausted to the steam generator for heat recovery, it would then be sent to the plant’s off-gas system. Before discharging through the building’s stack, the air flow would be sent through a selective catalytic reduction unit for control of nitrogen oxides in the off-gas. This system works by first injecting ammonia in the flue gas, which reacts in the presence of a catalyst to produce nitrogen gas and water. The selective catalytic reduction unit would reduce between 80 and 90 percent of the nitrogen oxides in the gas turbine exhaust (EPA 2008) and would be located at or near the steam generator in order to maintain necessary temperatures for the reaction.

The CHP plant was proposed with key roles played by the Seattle Steam Company and Puget Sound Energy (PSE), which is a local electricity and natural gas utility. Seattle Steam’s proposed function in the project is to lease the Post Avenue plant to a project developer with a contract to purchase steam. PSE would similarly be under contract with the CHP plant developer to sell natural gas and purchase electrical energy. PSE also expressed a possible interest in being

(24)

DOE Proposed Action and Alternatives

the owner of the CHP plant and supplier of steam energy to Seattle Steam. A third identified player, Seattle City Light (a public owned utility), agreed to provide electric connections to the Post Avenue plant facility and sell transmission services through its electrical system. Although PSE provides natural gas utility services in the city of Seattle, Seattle City Light is the sole provider of electricity in the city. PSE provides electricity to areas bordering the city.

Therefore, there would be transmission agreements and fees involved in moving the electrical energy from the CHP plant to the PSE distribution system where the energy would ultimately be sold and used.

A significant characteristic of the project site, specifically the Post Avenue building, is its location within the Pioneer Square – Skid Road Historic District, which is on both the

Washington Heritage Register and the National Register of Historic Places (DAHP 2009). In 2007, the Washington State Historic Preservation Office submitted a National Registration of Historic Places Registration Form to the National Park Service to document a more complete record of the existing resources within the district. The application expanded the number of resources designated as contributing to the Pioneer Square District’s placement on the National Register (SHPO 2007). The registration form increased the number of contributing sources from the 10 already on the National Register to 131. The Seattle Steam facility on Post Avenue was identified as two of the additional contributing sources: the “New Post Station, Seattle Steam Company” at 633 Post Avenue and the “Old Post Station, Seattle Steam Company” at 619 Post Avenue.

The 633 Post Avenue portion (Figures 2-4 and 2-5), designated the New Post Station in the registration form, was constructed in 1902 and is recognized for its striking architecture and as one of the last working remnants of the original industrial fabric of the Pioneer Square – Skid Road National Historic District. The building’s smokestack, visible in many parts of downtown Seattle, is also identified as an important visual marker within the city (SHPO 2007). The 619 Post Avenue portion, designated the Old Post Station in the registration form, was constructed in the 1890 timeframe and altered in 1903. It combines two masonry buildings that form a

structure of irregular shape and varying roof and floor levels (SHPO 2007). In Figure 2-4, it is the low building (partially covered with ivy) at the southern end of the New Post Station. Although 619 Post Avenue is the address on tax records for the entire facility, the CHP plant would be installed in the larger portion of the overall facility; that is, the portion designated as 633 Post Avenue on the National Register of Historic Places. This Draft EA refers to the location of the proposed project as 633 Post Avenue.

(25)

DOE Proposed Action and Alternatives

Figure 2-5. Interior views of the Seattle Steam plant at 633 Post Avenue, showing the steel

frame and concrete floor construction.

Figure 2-4. Photograph of the Seattle

Steam plant at 633 Post Avenue, showing the western side of the building (the side facing Western Avenue) and a portion of the Old Post Station (lower right).

(26)

DOE Proposed Action and Alternatives

2.3 Alternatives

The Department’s alternatives to its Proposed Action for the Industrial Technologies Program consist of other technically acceptable applications received in response to the Funding

Opportunity Announcement DE-FOA-0000044, Recovery Act: Deployment of Combined Heat and Power (CHP) Systems, District Energy Systems, Waste Energy Recovery Systems, and Efficient Industrial Equipment. Prior to selection, DOE made preliminary determinations

regarding the level of review required by NEPA based on potentially significant impacts identified during reviews of the technically acceptable applications. DOE conducted these preliminary environmental reviews pursuant to 10 CFR 1021.216 and a variance to certain requirements in the regulation granted by the Department’s General Counsel (74 FR 41693, August 18, 2009). These preliminary NEPA determinations and environmental reviews were provided to the selecting official for consideration during the selection process.

Because DOE’s Proposed Action under the Industrial Technologies Program is limited to

providing financial assistance in cost-sharing arrangements to projects submitted by applicants in response to a competitive funding opportunity, DOE’s decision is limited to either accepting or rejecting the project as proposed by the proponent, including its proposed technology and selected sites. The Department’s consideration of reasonable alternatives is therefore limited to the technically acceptable applications and a No-Action Alternative for each selected project.

2.4 No-Action

Alternative

Under the No-Action Alternative, DOE would not provide funding to Seattle Steam for the proposed CHP system. As a result, installation of the CHP system would be delayed while Seattle Steam looked for other funding sources, or abandoned if other funding sources could not be obtained. Furthermore, demonstration and adoption of advanced technologies and energy best management practices would not occur or would be delayed and DOE’s ability to achieve its objectives under the Industrial Technologies Program and the Recovery Act would be impaired. Although Seattle Steam’s proposed project might proceed if DOE decided not to provide any form of financial assistance, DOE assumes for purposes of this EA the project would not precede without this assistance. If the project did proceed without DOE’s financial assistance, the

potential impacts would be essentially identical to those under DOE’s Proposed Action (that is, providing assistance that allows the project to proceed). In order to allow a comparison between the potential impacts of a project as implemented and the impacts of not proceeding with a project, DOE assumes that if it decided to withhold assistance from this project, construction and operation of the Seattle Steam proposed CHP system would not proceed.

(27)

Affected Environment and Environmental Consequences

3. AFFECTED

ENVIRONMENT AND ENVIRONMENTAL

CONSEQUENCES

In this chapter, DOE assesses the following resources: air quality, cultural resources, socioeconomics, occupational health and safety, noise, utilities, energy, and materials. The “environmental baseline” for each of these resource areas is described first, followed by an assessment of the potential consequences of the proposed project and of the No-Action Alternative.

3.1 Air

Quality

3.1.1 AFFECTED ENVIRONMENT

The ambient air quality in an area can be characterized in terms of whether it complies with the primary and secondary National Ambient Air Quality Standards. The Clean Air Act (42 U.S.C.

7401 et seq.) requires the U.S. Environmental Protection Agency (EPA) to set national standards for pollutants considered harmful to public health and the environment. National Ambient Air Quality Standards have been established for six criteria pollutants: carbon monoxide; lead; nitrogen dioxide; ozone; particulate matter (including particulate matter with both an

aerodynamic size less than or equal to 10 microns and less than or equal to 2.5 microns); and sulfur dioxide. Primary standards define levels of air quality the EPA has determined necessary to provide an adequate margin of safety to protect public health, including the health of

“sensitive” populations such as children and the elderly. Secondary standards define levels of air quality deemed necessary to protect the public welfare, including protection against decreased visibility and damage to animals, crops, vegetation, and buildings.

Table 3-1 lists the National Ambient Air Quality Standards primary standards for each criteria pollutant. Regions that are not in compliance with the standards are designated “nonattainment” areas. Also shown in Table 3-1 are the most recent records available in EPA’s Air Data database for King County, Washington, which includes all of Seattle and much of the adjoining

metropolitan area, including just north of Tacoma, Washington. King County is currently classified as an attainment area for all criteria pollutants (EPA 2010), which is consistent with the latest ambient air quality data shown in the table, although no ambient air concentrations were available for lead. Based on the information in the table, 2006 was the last year with any nonattainment issues as indicated with the bolded values for ozone and PM2.5. Ambient air quality values reported for 2007 and 2008 were all within applicable air quality standards. If a region is identified as a nonattainment area, the state is required to develop and implement plans to bring the region into compliance with ambient air quality standards. Once the region has attained the standard, the state is required to develop a maintenance plan to keep it in compliance. According to EPA’s Green Book (that is, EPA’s web-based records on nonattainment areas found at http://www.epa.gov/air/oaqps/greenbk), all of King County, Washington, requires a maintenance plan for ozone to keep the County in compliance with

(28)

Affected Environment and Environmental Consequences

ambient air standards for ozone. The Green Book also identifies the Seattle-Tacoma urban area as a maintenance area for carbon monoxide. The existing Seattle Steam plant is within both of these air quality maintenance areas.

Table 3-1. National Ambient Air Quality Standards and air quality data for King County,

Washington in 2006, 2007, and 2008.

Pollutant

National Ambient Air

Quality Standardsa Ambient air quality in King County, WAb Averaging

period

Primary

standard 2006 2007 2008

Carbon monoxide 8 hours 9 ppm 3.4 ppm 2.6 ppm 1.9 ppm

1 hour 35 ppm 4.4 ppm 3.5 ppm 3.1 ppm

Lead Quarterly 1.5 μg/m3 Not Available Not Available Not Available Nitrogen dioxide Annual 0.053 ppm 0.018 ppm Not Available Not Available

Ozone 8 hours 0.075 ppm 0.087 ppm 0.068ppm 0.075 ppm

1 hour 0.12 ppm 0.129 ppm 0.091 ppm 0.104 ppm

PM10 Annual 50 μg/m3 26 μg/m3 20 μg/m3 Not Available 24 hours 150 μg/m3 63 μg/m3 58 μg/m3 Not Available PM2.5 Annual 15.0 μg/m3 12.09 μg/m3 9.59 μg/m3 10.12 μg/m3 24 hour 35 μg/m3 37.3μg/m3 30.3 μg/m3 33.4 μg/m3 Sulfur dioxide Annual 0.03 ppm Not Available 0.002 ppm 0.001 ppm

24 hours 0.14 ppm Not Available 0.007 ppm 0.011 ppm

a. Source: 40 CFR 50.4 through 50.13. b. Sources: EPA 2009a, 2009b, and 2009c.

g/m3 = micrograms per cubic meter.

PM10 = particulate matter with median aerodynamic diameter of 10 micrometers or less. PM2.5 = particulate matter with median aerodynamic diameter of 2.5 micrometers or less. ppm = parts per million.

3.1.2 ENVIRONMENTAL CONSEQUENCES

3.1.2.1 Proposed Project

Impacts on air quality during installation of the CHP system would be short term and negligible. The primary source of air pollutants during installation would be vehicle exhaust from the operation of heavy equipment such as trucks, forklifts, and cranes. These activities would be temporary, occur in a localized area, and be very small compared with the emissions from vehicles and other sources in the Seattle area. The project would involve no earthwork, and fugitive dust emissions from other types of work would be minor.

Air emissions from the CHP system would include the products of combustion from the gas turbine, which would be incorporated into the air exhausted to the steam generator. At the duct between the gas turbine and the steam generator, additional products of combustion would join the flow when additional fuel was added at that point (Figure 2-3). The primary fuel for the CHP

(29)

Affected Environment and Environmental Consequences

system would be natural gas, but as with the existing steam boiler, the CHP system would be configured to support the use of fuel oil during periods of natural gas curtailment. The air emissions from the CHP plant would include the criteria pollutants carbon monoxide, nitrogen dioxide, particulate matter (that is, PM10 and PM2.5), and sulfur dioxide. In addition, emissions would include volatile organic compounds (VOCs), an ozone precursor. Table 3-2 provides the preliminary estimate of the quantities of these criteria pollutants that would be emitted from the CHP plant during a single year. The plant’s off gas would not be expected to include lead, but Seattle Steam did estimate the amounts of other hazardous air pollutants that would be present; this estimate is provided in the table. For comparison with the emission estimates for the

proposed CHP plant, Table 3-2 also shows the current permit limits for the existing plant and the reported annual emissions for all of King County, Washington. Seattle Steam operates its Western Avenue and Post Avenue facilities as a single plant. The operating boiler at the Post Avenue facility, because it is the least efficient, is last on the list of boilers to be used in response to increased energy demand. As a result, air emissions from the Post Avenue facility have been well below permit limits in recent years.

Table 3-2. Preliminary estimates of air emissions from the Seattle Steam proposed CHP plant

compared with existing energy plant permit limits and King County total emissions.

Pollutant

Emissions (tons per year) Proposed

CHP planta Existing energy plant – allowed by permitb King County in 2005 (2002 for HAPs)c

Carbon monoxide 23 Not in current permit 561,582

Nitrogen oxides 19 < 99 74,193

PM10 83 Not in current permit 21,488

PM2.5 83 Not in current permit 7,374

Sulfur dioxide 6 < 99 6,643

Volatile organic compounds 12 Not in current permit 83,157 Hazardous air pollutantsd 0.63 Not in current permit 5,082

a. Source: Seattle Steam 2009. b. Source: PSCAA 1999.

c. Sources: EPA 2009d for HAPs, EPA 2009e for others.

d. The HAPs value reported is for the sum of 33 urban hazardous air pollutants.

As Table 3-2 shows, the estimated emissions from the proposed CHP plant would be well below the existing permit limits for the regulated pollutants nitrogen oxides (NOX) and sulfur dioxide. The estimated emissions would represent a very small portion of King County’s total annual emissions. Although the available comparisons in the table indicate the proposed project’s air emissions would be relatively minor, the project has not yet initiated formal permitting actions, which would require more detailed analysis and would establish specific requirements for the proposed project. According to Seattle Steam, the permit application would include criteria and toxic air pollutant emission rate calculations, a regulatory analysis, a best available control technology analysis, and air dispersion modeling analyses to evaluate compliance with ambient standards or other regulatory requirements. Based on preliminary conversations with the applicable regulatory agency, the Puget Sound Clean Air Agency (PSCAA), Seattle Steam

(30)

Affected Environment and Environmental Consequences

expects that required air dispersion modeling will include both ground-level and on-building receptors as was done in the modeling analysis developed in support of its Western Avenue facility wood-fired boiler project. Seattle Steam anticipates the project would not be subject to the Prevention of Significant Deterioration (PSD) air permit program.

3.1.2.1.1 Air Quality Conformity

Section 176(c) (1) of the Clean Air Act requires federal agencies to ensure that their actions

conform with applicable implementation plans for the achievement and maintenance of the National Ambient Air Quality Standards for criteria pollutants (DOE 2000). To achieve conformity, a federal action must not contribute to new violations of standards for ambient air quality, increase the frequency or severity of existing violations, or delay timely attainment of standards in the area of concern. The EPA general conformity regulations (40 CFR 93, Subpart B) contain guidance for determining whether a proposed federal action would cause emissions to be above specified levels in nonattainment or maintenance areas.

A conformity determination is not required if estimated emissions of criteria pollutants are: (1) below applicable threshold emission rates for nonattainment or maintenance areas; and (2) below 10 percent of the nonattainment or maintenance area’s emission inventory for the pollutants of concern (DOE 2000). Seattle Steam’s proposed CHP project would occur in an area that is in attainment for all criteria pollutants, but in maintenance areas for ozone and carbon monoxide (CO). Threshold emission rates for ozone in a maintenance area are established in terms of the ozone precursors NOX and VOCs and both are set at 100 tons per year [40 CFR 93.153(b)(2)]. The threshold emission rate for CO in a maintenance area is similarly set at 100 tons per year. As can be seen in Table 3-2, estimated emissions of CO, NOX, and VOCs from the proposed CHP system are each below the threshold rate of 100 tons per year, and each is well below 10 percent of the corresponding quantity emitted in King County during a year. The maintenance area criteria pollutant that would be emitted at the largest percentage of the County’s total emissions would be NOX, but it would represent less than 0.03 percent of the County’s annual emissions. Although not an applicable maintenance area pollutant, PM2.5 emissions, at about 1.1 percent, would represent the highest portion of the County’s total annual emissions. Since the proposed project would not exceed the applicable threshold emission rates and would not represent 10 percent or more of the area’s emissions inventory for these pollutants, no conformity determination under the Clean Air Act would be necessary (DOE 2000).

As noted above, Seattle Steam does not expect that its proposed project would require a PSD permit; however, other operating permit requirements set by Washington and the PSCAA would be applicable. If Seattle Steam was required to obtain a PSD permit, a conformity determination would still be unnecessary. In accordance with EPA regulations at 40 CFR 93.153(d)(1), the conformity determination requirements do not apply to federal actions if “the portion of an action includes major new or modified stationary sources that require a permit under the new source review program (Section 173 of the [Clean Air] Act) or the prevention of significant

(31)

Affected Environment and Environmental Consequences

was issued under regulations developed pursuant to the EPA’s new source review program, the conformity determination would not be required.

3.1.2.1.2 Greenhouse Gas Emissions

The burning of fossil fuels, such as natural gas, diesel, and gasoline, emits carbon dioxide, which is a greenhouse gas. Greenhouse gases can trap heat in the atmosphere and have been associated with global climate change. The Intergovernmental Panel on Climate Change, in its Fourth Assessment Report issued in 2007, stated that warming of the earth’s climate system is

unequivocal, and that most of the observed increase in globally averaged temperatures since the mid-20th century is very likely due to the observed increase in concentrations of greenhouse gases from human activities (IPCC 2007). Greenhouse gases are well mixed throughout the lower atmosphere, such that any emissions would add to cumulative regional and global concentrations of carbon dioxide. The effects from any individual source of greenhouse gases therefore cannot be determined.

The basis of Seattle Steam’s proposed CHP system is that it provides very efficient use of the fuel that would be combusted in the gas turbine and at the duct leading to the steam generator. The CHP system’s combustion processes would result in carbon dioxide emissions [estimated at about 207,000 tons per year (Seattle Steam 2009)]; the emissions would be offset by reductions in the carbon dioxide emissions of the existing steam boiler and the reduction of emissions from traditional electricity production plants. If it is assumed that the electricity produced by the proposed CHP system reduces the amount of electricity produced from some other fossil fuel-fired generation plant, then there would be an expectation of a net decrease in carbon dioxide production. That is, the carbon dioxide produced by the CHP system should be less than what would be produced from the existing steam plant plus the increment from a fossil-fuel fired electricity generation plant. Based on the anticipated improved energy efficiency of the CHP system, the carbon dioxide emissions estimated for the new plant would be expected to be only 60 to 75 percent of the carbon dioxide emissions now resulting from the production of

comparable quantities of heat and power.

3.1.2.2 No-Action Alternative

Under the No-Action Alternative, DOE would not provide funding to Seattle Steam for the proposed CHP system, and DOE assumes the project would not proceed without this assistance. Further, Seattle Steam would continue to obtain steam from the existing boiler and there would be no change in emissions of pollutants from this plant; however, there would be no beneficial decrease in regional emissions of pollutants from the use of the energy-efficient CHP system.

(32)

Affected Environment and Environmental Consequences

3.2 Cultural

Resources

3.2.1 AFFECTED ENVIRONMENT

This section describes the existing cultural resource conditions in the area of the proposed project site. The area of potential impacts to cultural resources includes the existing Seattle Steam facility on Post Avenue and property adjacent to the proposed project area that could be affected by the action, during construction and/or during operation of the CHP plant. Cultural resources are historic properties as defined by the National Historic Preservation Act, cultural items as

defined by the Native American Graves and Repatriation Act, archaeological resources as

defined by the Archaeological Resources Protection Act, sacred sites as defined in Executive

Order 13007 to which access is afforded under the American Indian Religious Freedom Act, and

collections and associated records as defined in 36 CFR Part 79. Since the proposed project would occur in the downtown area of Seattle, Washington, and would only involve alterations to and work inside an existing building, only the historic properties as defined by the National Historic Preservation Act would be of concern. The following material summarizes the historic

background of the area, followed by the status of cultural resources inventories and consultations.

3.2.1.1 Historic Background

The area known locally as Pioneer Square is the site of the first permanent European settlement in what is now Seattle, Washington. Settlers selected the site because it was the only flat area along the deep and protected harbor on Elliot Bay. In 1853, Henry Yesler began operating a steam saw mill near what is now the intersection of Yesler Way and First Avenue. Logs from the hillsides to the east were skidded down to the saw mill and the wharf. This began the terminology of “skid road” and business activity grew up near the mill, primarily along what is now First Avenue South (Seattle n.d.).

In 1889, a fire destroyed approximately 30 blocks of mostly wood buildings in the city’s central core. The local economy was strong at the time and rebuilding began almost immediately, but as a result of the fire, the City Council passed an ordinance requiring buildings to be constructed of brick and stone. In this same time frame, much of the city’s boggy, marshy ground was filled in and street levels were raised. Because the area was rebuilt quickly (most occurring within two years) and primarily designed by a handful of architects, the buildings are generally considered to be of unusually harmonious architectural character.

The Pioneer Square area had its heyday in the late 1890s during the Alaska gold rush, but this began changing after the turn of the century, and the city’s commercial district began moving toward the north, primarily along Second Avenue. Correspondingly, the Pioneer Square area began changing to a “honky-tonk district of taverns, entertainment houses and bawdy hotels” (Seattle n.d.). Redevelopment of this area became a low priority, and the turn-of-the century buildings remained largely intact. In the 1960s and 1970s, merchants and citizens began campaigns to restore the area and recognize its historic significance and commercial potential.

(33)

Affected Environment and Environmental Consequences

The Pioneer Square – Skid Road District first appeared on the National Register of Historic Places in 1970.

3.2.1.2 Status of Cultural Resource Inventories and Section 106 Consultations

The Department searched the National Register of Historic Places to identify historic places near the proposed project site. The National Park Service plotted National Properties into Google Earth layers so the properties could be located via the internet. Figure 3-1 provides the results of the data search in the area of the proposed CHP plant. The figure shows sites within 0.5 mile of the project site, labeled with numbers that correspond to the information presented in Table 3-3. Taking the search radius to 0.5 mile was done in order to include all of the Pioneer Square – Skid Road Historic District, which extends to the south as far as just beyond (toward the bottom of the figure) locations 19 and 25 in the figure.

Figure 3-1. Locations of properties on the National Resister of Historic Places (with labels

(34)

Affected Env ironment and Environment al Consequences DOE/EA-1741D 22

Table 3-3. Properties on the National Resister of Historic Places within 0.5 mile of the proposed project site (with number

designations per Figure 3-1).

Historic Place Name Address Description

NPS Ref.

No. Date listed

Distance from project site

(miles) 1. Iron Pergola 1st Ave and Yesler Way 1909, elaborate waiting shelter for cable

car

71000875 08/1971 0.06

2. Pioneer Building, Pergola, and Totem Pole

1st Ave and Yesler Way 1892, 6-story brick masonry and stone

building, totem pole from Alaska

77001340 05/1977 0.07

3. Colman Building 811 1st Ave 1904, 6-story, concrete and brick

building

72001272 03/1972 0.07

4. Hoge Building 705 2nd Ave 1920, 17- to 18-story, brick and

ast-stone building

83003339 04/1983 0.10

5. Old Federal Office Building 909 1st Ave 1933, 11-story (at highest portion) Art Deco building and the first building in Seattle built specifically for federal offices

79003155 04/1979 0.12

6. Pioneer Square – Skid Road District

Roughly bounded by Elliot Bay, King, 3rd, Columbia,

and Cherry Sts

52-acre district with buildings of distinctive and homogeneous late Victorian style

70000086 06/1970 0.15 (to dot in Figure 3-1)

7. Lyon Building 607 3rd Ave 1910, 6-story, reinforced concrete and

block building

95000806 06/1995 0.17

8. Rector Hotel 619-621 3rd Ave 1911, 6-story building with reinforced

concrete structure with brick, terra cotta, and limestone surfaces

02000809 08/2002 0.17

9. Arctic Building 306 Cherry St 1916, 8-story building with terra cotta panels over a steel reinforced concrete frame

78002749 11/1978 0.17

10. Pioneer Square – Skid Road District (boundary increase)

Roughly bounded by the Viaduct, King St, 6th and 5th

Aves, James and Columbia Sts

See #6 – district size increased to 88 acres

7800341 07/1978 0.19 (to dot in Figure 3-1)

Figure

Table 1-1.  Resource areas with no or minimal impacts (continued).
Figure 2-1.  Locations of Seattle Steam’s energy generation plants and district energy  system
Figure 2-2.  Aerial view of the Seattle Steam plant on Post Avenue, Seattle.
Figure 2-5.  Interior views of the Seattle Steam plant at 633 Post Avenue, showing the steel  frame and concrete floor construction
+7

References

Related documents

As for AIMP3, ERCC1 expression was interrogated in the Radical Cystectomy set in order to answer the question whether ERCC1 status was simply prognostic of survival in bladder

Baccalaureate institutions party to this agreement include: University of Washington, Seattle; Washington State University; Northwest University; Seattle University; Seattle

A Feminist Approach to Post-Obamacare Health Reform, Albany Law School, February 1-2,. 2013, Northeast Regional Junior Faculty Scholarship and Teaching Development Workshop

Estos datos revelan cierta pervivencia de los estereotipos de género tradicionales en lo que respecta a la concepción del cuerpo masculino en cuanto que prevalece la atribución

In order to effectively deliver tumor antigens to DCs and trigger a strong anti-tumor immune response, herein, a specific DCs target delivery system was assembled by using

You also have the legally protected right to examine the annual report at the main office of the plan (Seattle University, 901 12th Avenue, Seattle, WA 98122) and at the

Diplomskim radom prikazat će se trenutno stanje skijaških centara u Gorskom kotaru, utvrditi stanje sportskih klubova koji se bave sportovima na snijegu, te navesti moguće

Haplern N (2007) The Impact of Attendance and Student Characteristics on Academic Achievement: Findings from an Undergraduate Business. Management Module Journal of Further and